丛枝菌根对盐胁迫的响应及其与宿主植物的互作

丛枝菌根真菌(Arbuscular Mycorrhizae Fungi,AMF)作为陆地生态系统的组成部分之一,在促进宿主植物对土壤养分和水分的吸收、提高植物生物量生产、调节种群和群落的结构、维持生态系统的稳定性等方面发挥了重要作用。其中,盐渍化是自然生态系统中广泛存在的一种胁迫生境条件,全球盐渍化土地约占耕地总面积的10%,因而探讨AM菌根在此胁迫生境下对宿主植物生长的影响具有重要意义。从以下几个方面,围绕盐胁迫条件、AM菌根和宿主植物三者之间的关系对当前国际上相关领域的研究进展进行了综述:1)AM真菌对盐胁迫的响应,包括菌根共生体形成、菌根侵染率、AM真菌的分布、菌丝体生长发育、孢子的形成和分布等;2)盐胁迫条件下AM菌根对宿主植物的效应,包括AM菌根促进宿主植物对P、N等元素的吸收、降低植物体内Na 的含量、提高光合作用能力,进而提高植物的生物量和对植物的群落结构产生影响等;3)AM菌根提高宿主植物耐盐性的机理,分别从植物根系形态的改变、水分吸收能力的加强、细胞内营养物质的平衡,以及细胞生理代谢的调节等方面对AM菌根促进植物抗盐性的机理进行了剖析。     

一株甲醛降解真菌Aspergillus spp.H4的分离鉴定

甲醛是一种广泛使用和很重要的化工原材料,但它同时也是对大多数生物有机体有高毒性的物质。通过添加甲醛的选择性培养基从淤泥里分离了一株甲醛耐受真菌,将其接种于加孟加拉红的PDA培养基、察氏培养基、麦芽汁培养基平板培养,观察它的培养特征和孢子结构,结合DNA提取、PCR扩增、产物测序、GenBank比对等分子鉴定手段,结果表明:其培养特征、显微特征和黄曲霉(Aspergillus flavus)相似,18SrDNA序列与黄曲霉(Aspergillus flavus)同源率达99.8%。我们把它命名为Aspergillus flavus H4。该真菌最适生长pH值为pH5.5,在培养的144h内ρ(甲醛)从1241mg·L-1下降到4mg·L-1。在培养的96h内ρ(甲醛)下降迅速,A值上升缓慢,当ρ(甲醛)下降到10mg·L-1时,也就是120h时,A值迅速上升,ρ(甲醛)下降缓慢。结论是这株Aspergillus flavus H4是甲醛耐受(降解)真菌。     

3株真菌对毒死蜱的降解特性

从污水排放口污泥中分离到3株以毒死蜱为唯一碳源生长的真菌WZ-Ⅰ、WZ-Ⅱ、WZ-Ⅲ,鉴定均为镰孢霉属(FusariumLK. exFx). 3株菌5d内对50mgL-1毒死蜱的降解率分别高达93. 5%、91. 4%和83. 5%.测定了不同碳源、pH、温度及毒死蜱浓度对真菌降解能力和生长量的影响.结果表明,以毒死蜱为唯一碳源且其浓度为20~200mgL-1,pH6. 5~9. 0,温度30 ~40℃时,真菌的降解效果较好;真菌生长量随外加碳源浓度的增加而增加,在pH 6. 5 ~9. 0时生长量较大,且当毒死蜱浓度为50mgL-1,温度40℃时其生长量最大. 图5表1参18     

不同AM真菌对三叶草耐油性的影响

在盆栽条件下研究了4个油浓度（0、5000、10000和50000w/mgkg^-1）下接种辽河油田污染土壤中分离出的3种AM真菌（Glomus mosseae，G.geospora，G.constrictum）对三叶草耐油性的影响。试验结果表明：1）随着油浓度的增加，侵染率亦增加，10000mgkg^-1时G.geospora和G.constrictum的侵染率分别为67.65％和82.86％；2）从侵染率、地上部生物量和菌根依赖性来看，随着油浓度的增加，最适的AM真菌亦不一样，油浓度为0、5000和10000mgkg^-1时，最适AM真菌分别是G.geospora、G.mosseae和G.constrictum；3）油污染土壤上接种AM真菌能促进植株的地下部和地上部的生长，接菌处理的茎干重比相应的对照增加62.2％-267.1％；4）随着油浓度的增加和植物的生育进程，AM真菌的接种效应在增强。图3表3参14     

外生菌根真菌接种和施磷对油松苗抗盐性的影响

采用3种不同的外生菌根真菌Boletus edulis、Xerocomus chrysenteron和Gomphidius viscidus，在山东东营盐渍土环境胁迫下，研究外生菌根真菌接种和施磷对油松(Pinus tabulaeformis)生长的影响及其可能机理。结果表明，接种和施磷都增加了油松植株的干质量，但施磷不如接种对植物生长的促进作用明显；接种外生菌根后，油松体内的K元素含量显著增加，而Na元素的含量没有明显变化，使得w(K)／w(Na)增加，从而改变了植株体内的离子平衡，减轻离子的毒害作用。而不是通过直接减少植物对Na的吸收来增加植物的抗盐性；同时，接种后外生菌根增加了油松对P的吸收，改善了盐渍土壤导致的植物营养亏缺，促进了植物在盐渍环境下的生长。     

染料浓度和盐度对白腐真菌同工酶的电泳分析

应用聚丙烯酰胺凝胶电泳技术分析,并比较了染料废水的两大因子(染料浓度和盐度)对黄孢原毛平革菌过氧化物同工酶谱带的影响程度,结果表明:在染料或盐胁迫下,黄孢原毛平革菌均表现出应急产酶的响应,虽然过氧化物同工酶谱带数量未发生增加或减少,但谱带强度受到较大影响,活性艳红X-3B浓度≤200mg/L或NaCl浓度≤15g/L时均能诱导过量产酶,继续提高染料浓度或盐度将导致产酶抑制,染料浓度对酶带的影响作用高于盐度。     

Arbuscular mycorrhizal fungi can decrease the uptake of uranium by subterranean clover grown at high levels of uranium in soil

Subterranean clover inoculated or not with the arbuscular mycorrhizal (AM) fungus Glomus intraradices was grown on soil containing six levels of 238U in the range 0-87 mg kg(-1). Increasing U concentration in soil enhanced the U concentration in roots and shoots of both mycorrhizal and nonmycorrhizal plants but had no significant effects on plant dry matter production or root AM colonization. Mycorrhizas increased the shoot dry matter and P concentration in roots and shoots, while in most cases, it decreased the Ca, Mg and K concentrations in plants. The AM fungus influenced U concentration in plants only in the treatment receiving 87 mg U kg(-1) soil. In this case, U concentration in shoots of nonmycorrhizal plants was 1.7 times that of shoots of mycorrhizal plants. These results suggested that mycorrhizal fungi can limit U accumulation by plants exposed to high levels of U in soil.     

The Influence of Mycorrhiza on Uranium and Phosphorus Uptake by Barley Plants from a Field-contaminated Soil (7 pp)

Background Recent studies indicated that arbuscular mycorrhizal fungi (AMF) play important roles in plant accumulation of uranium (U) from contaminated environments, but the impacts of fertilization practices on functioning of the symbiotic associations, which are crucial factors influencing plant nutrition and growth responses to mycorrhiza, have rarely been considered. Materials and Methods In a greenhouse experiment, a bald root barley mutant (brb) together with the wild type (wt) were used to test the role of root hairs and AMF in uranium (U) uptake by host plants from a U contaminated soil. Nil, 20 and 60 mg KH2PO4-P kg–1 soil were included to investigate the influences of phosphorus (P) fertilization on plant growth and accumulation of U. Results Dry matter yield of barley plants increased with increasing P additions and wt produced significantly higher dry weight than brb. Mycorrhiza markedly improved dry matter yield of both genotypes grown at nil P, whereas only brb responded positively to mycorrhiza at 20 mg P kg-1. At the highest P level, mycorrhiza resulted in growth depressions in both genotypes, except for the roots of wt. In general, plant P concentrations increased markedly with increasing P additions and in response to mycorrhiza. Mycorrhiza and P additions had no significant effects on shoot U concentrations. However, root U concentrations in both genotypes were significantly increased by mycorrhiza. On the other hand, shoot U contents increased with increasing P levels, while 20 mg P kg-1 stimulated, but 60 mg P kg-1 marginally affected the U accumulation in roots. Root length specific U uptake was moderately enhanced both by root hairs and strongly enhanced by mycorrhiza. Moreover, non-inoculated plants generally had higher shoot-root ratios of U content than the corresponding inoculated controls. Conclusion Our study shows that AMF and root hairs improves not only P acquisition but also the root uptake of U, and mycorrhiza generally decreases U translocation from plant root to shoot. Hence, mycorrhiza is of potential use in the phytostabilization of U contaminated environments. Perspectives The complex impacts of P on U accumulation by barley plants suggested that U behavior in mycorrhizosphere and translocation along the soil-fungi-plant continuum as affected by fertilization practices deserve extensive studies for optimizing the function of mycorrhizal associations for phytoremediation purposes.     

活性红M-3BE脱色真菌的筛选及脱色性能研究

从自然环境中分离到2株对染料活性红M-3BE具有明显脱色效果的真菌,经形态学和26S rDNA序列分析,将其鉴定为Fusarium oxysporum和Geosmithia viridis.采用初始浓度50 mg/L M-3BE的液体培养基同步脱色培养,F.oxysporum在24 h内对M-3BE的脱色率为96%,G.viridis在36 h内的脱色率为82%.对脱色酶系的检测结果表明,脱色过程中F.oxysporum能产生LiP和MnP,G.viridis则仅产生LiP.此外,F.oxysporu和G.viridis对另外7种染料的脱色率也可分别达到16%～100%和83.3%～100%.     

堆肥中纤维素和木质素的生物降解研究现状

堆肥是垃圾处理的主要方法之一 ,厨房垃圾、园林垃圾、农村秸秆和日常生活中的废弃纤维产品均可作为堆肥原料 ,这些原料中含有一定量的纤维素和木质素 ,而纤维素和木质素在堆肥过程中较难生物降解。因此 ,国内外学者致力于研究能加速纤维素和木质素降解的高效微生物。研究发现 ,对纤维素和木质素有降解能力的微生物主要是高温放线菌和高温真菌 ,其中有独特降解机制的白腐菌在木质素降解中起着重要作用